Method of making glass wool



.Iunel6,1942. D; LEIST ET A; 2,287,007

METHOD OF MAKING GLASS WOOL Original Filed April 14, 1937 3 Sheets-Sheet l ll l vENTCiR o'" ,Dale Kleist 77??? ATTORNEY June 16, 1 942. D KLEIST ET AL 2,287,007

METHOD OF MAKING eL'Ass WOOL I Original Filed April 14, 1937 3 Sheecls-Sheet 2 J3 4o I 1 'ffig '5 I i A 7' 9 4- E l i J0 4 1 3 l I I 63 [:1 IL II 1 ao i 4 6. f {UP 1 4/7 1 157 I J5 0 [:1 C] I: 5 l l 4/0 J JG 4 6 '46 41 6 J0 6'0 J0 J3 53 J0 J2 1 153 412 A INVENTORS Dale Kleist w ATTORNEY 3 Sheets-Sheet 5 INVENTORS le Klezlst w BY Games Sia yter K" {50mm D. KLElST ETAL June 16, 1942.

METHOD OF MAKING GLASS WOOL Original Filed April -14, 1937 Patented June 16, 1942 UNITED STATE s PATENT OFFICE METHOD OF MAKING GLASS WOOL Original application April 14, 1937, Serial No.

136,893. Divided and this application Sep-' tcmber 25, 1939, Serial No. 296,373

12 Claims. (Cl. 154-28) Our invention relates to methods for use in the manufacture of inorganic fibrous material in matted form, by a continuous process which comprises flowing the molten material in small streams, continuously drawing and attenuating said streams in the form of fine fibers by means of blasts of steam or other gas, and causing the fibers as they are formed to solidify and accumulate in matted form on a conveyor mechanism by which the mat, as it is formed, is advanced continually in mat form.

The invention more particularly relates to the step of expanding gradually the vehicular steam blast by means of a novel form of hood or spout through which the fibers, during their formation, are carried by the blast, and from where they are deposited upon a suitable support or platform such as a chain belt or the like, where they build up into an interfelted matted form.

Heretofore in the use of barrels or hoods adapted to guide the blast of gases-and the fibers onto a collecting platform or surface, great difficulty was experienced in forming a uniform, light, fluffy mat which was free from clots, rolled balls, knots, uneven places, and the like. Another difficulty experienced was caused by the high back pressure built up in the interior of the hood heretofore used, this causing a large amount of gases to blow out of the top of the hood, carrying with it large amounts of glass wool which blew all over the room and adhered. to the sides of the bushing or outlet orifices of the supply body, where it reheated, fused, and flowed down.to the outlet openings, where it interfered with the formation of the fibers. As a matter of fact, the air was so filled with fibers that it was almost unbreakable to work in the vicinity of the hood.

. Moreover, the glass fibers which blew out of the side of the hood or openings thereof, accumulated around the blower and actually clogged the jets thereof with glass. In addition, when using the old hoods, it is necessary to provide suction means underneath the accumulating belt in order to assist the passage of gas therethrough. It was also difiicult when applying coating substances in the form of emulsions or the like, to maintain the proper temperature conditions within the hood for obtaining maximum distribution of the coating material without producing a wet, soppy mass, or without causing the coating substances to impinge upon and collect in material quantities upon the side walls of the hood from where they might drop in gobs upon the mat.

In the use of the barrels or hoods of the prior up a uniformly felted mass of fibers, particularly if the fibers were deposited from a plurality of individual blasts of gas. There was a strong tendency to form thick and thin spots throughout the mat, and to find the mat filled with knots or lumps which seriously affected both the density of the mat and theheat efllciency thereof.

An object of the present invention is to overcome the foregoing difliculties found in the prior art.

Another object of the present invention is to controllthe passage of gaseous blasts and the indraft of air induced by the'blast; and to do this in a manner permitting the blast to obtain a high efiiciency in attenuating the fibers, and in such a manner that the fibers are prevented from being scattered or blown outside the hood or carried back to the feeder outlet from which the ma: terial issues.

A further object of the invention is to provide a novel type of streamlined spout 0r hood by which the passage of the downwardly moving blasts of gas and the fibers carried therewith are controlled, and the fibers are caused to accumulate in a compact, evenly distributed mat or web on a traveling screen conveyor therebeneath.

Another object of the invention is to provide means for building a compact, uniformly inter-. felted and intermatted bat without the necessity for a compacting chain overlying the mat or a compressing roll, and without the necessity of the usual suction fan underneath or behind the conveyor screen. We have found that by designing the contours of the hoods or spouts properly, it is possible to cause all of the blasts to be carried away smoothly and easily without a material loss of energy, without excess turbulence tending to break up the fibers into small pieces and shorter lengths, and without the necessity of additional artificial means to carry away and discharge the spent gases.

Still another object of the invention is to provide a nozzle or mouth opening having the proper contours adapted to admit and even suck in all of the steam blasts and the accompanying fibers, and also to admit a predetermined amount of induced air from the surrounding atmosphere; and to do this without causing a gaseous disturbance,

' or vibration, or loud noise, to occur at the mouth opening.

Other objects and advantages of the present invention will become apparent from the following description taken in conjunction with the drawings, in which:

art, great difflculty was experienced in building Fig. 1 is a part sectional side elevational view showing the glass melting furnace, the feeding mechanism, blowers, spouts, accumulating hoods, and a portion of the horizontal conveyor mechanism upon which the mat is formed and by which it is advanced in the form of a continuous mat;

Fig. 2 is a part sectional elevational view su stantially at the line 2-2 on Fig. 1;

Figs. 3 to 8, inclusive, illustrate the spouts through which the material is blown during the fiber forming process, or shortly thereafter;

Fig. 3 is an elevation of the battery of spouts; I

' pending application filed by us April 14, 1937, Se-

rial Number 136,893, and a continuation in part of the application filed by us October 1, 1935, S. N. 43,072.

One of the principal features of the present invention is the provision of a Venturi spout or nozzle into which the steam blast is projected. The mouth of the spout is preferably provided with a slightly flaring opening adapted to admit the gaseous blast and induced air in a smooth, streamlined flow, and to inhibit excessive turbulence, vibration and noises at this point. The venturi or nozzle acts as a steam pump, building up sufiicient pressure in the lower part of the forming hood to felt or pack the fibers and force the steam and induced air through the open work conveyor or belt at the lower end of the hood, without causing the pressure to build up to excessive amounts which would tend to blow part of the wool and the steam out of the top of the nozzle or mouth opening.

The hood itself is of gradually expanding cross section from the mouth of the nozzle down to the belt, and in this manner we gradually expand and decelerate the vehicular steam blast in velocity so that only a sufficient predetermined amount of energy in the steam is used to form I effect or action, in which all 01 the fibers arecaused to suck in through the mouth of the hood without permitting any of them to blow out and be lost.

Another feature of the expanding streamlined contours of the hood is the reduction or minimization of undesirable turbulence which would cause the fibers to break up into short hairy lengths or chail's.

Referring particularly to Fig. 1, a glass melting and refining tank isprovided with a fore-' hearth 36 within which a head of glass is maintained. The glass flows continuously through the feeder outlet in the floor of the boot, in a multiplicity of small streams 31 which are acted upon by blowers 38. The issuing streams of glass are enveloped in the downward blast of steam or other gas supplied by the blowers and are thereby continuously drawn out into fine filaments or fibers 39.

r from the blowers.

The feeder and blower mechanisms are not illustrated in detail, as they do not in themselves form a part of the present invention. They may be constructed and operated in the manner illustrated and described in the United States patent to Slayter and Thomas, No. 2,133,236, October 11. 1938.

Vertically disposed spouts 40 individual to the blowers 88 are positioned with their open upper ends directly beneath and spaced a short distance The steam blast from each blower is thus directed downward through a .spout 40, carrying with it the attenuated fibers II. The spouts ll are of streamlined formation, the walls of each spout being downwardly divergent and having their upper marginal portions 4| curved to provide a flared mouth, (see Figs. 3 to 8). The spout I is of the Venturi type, the shape and arrangement being such that an indraft of air is induced by the drawing force oi the steam blast, so that a considerable volume of air is drawn into and intermixed with the steam. The induced air entering radially from the surrounding atmosphere into the spout prevents any fibers from being thrown outside of the mouth opening where they would be lost. The Venturi action provides a suction and a strong downward draft free from excessive turb'ulence or eddy currents. This construction also eliminates back pressures and backdrafts by which part of the forming fibers may be carried upward through the upper end of the spout.

The lower ends of the spouts 40 open into an expansion hood or chamber 42 which is also of streamlined and expanding construction and forms an accumulating chamber within which the groups of fibers from the several spouts are mixedor combined and matted together to form a mat or web 43 which, as it forms, is continuously carried forward beyond the hood by a traveling conveyor 44. The conveyor is supported on rollers 34.

The chamber 42 is gradually expanding in horizontal cross-section, thus permitting a gradual expansion of the gases as they flow in smooth streamline. The main portion of the increase in horizontal cross-section is due to the divergent angle of the rear wall 90 forming the tail of the hood. The forward wall Si is designed to present a minimum of expansion for the gases, and its contours more or less conform to the straight streamlined flow of the fibers as they descend through the spout 40 and down upon the belt II. This permits the kinetic energy or inertia of the individual fibers to throw themselves directly upon the belt 44, freeing themselves from the. vehicular gases which tend to expand toward thetail of the hood which flares divergently toward the rear. As a result a large portion of the vehicular gases are permitted to pass through the belt 44 near the tail end of the hood where the fibers have packed themselves less densely than at the forward end of the hood directly under the spout.

The battery of spouts ll, as shown in Figs. 3 to 8, is preferably arranged in pairs, the pairs of spouts being preferably placed side by side so as to form two rows of spouts. Eachspout is adjustably supported by means of stop bolts 44', the latter being adjustable vertically on the spout and supported on ledges 45 at the upper end of the manifold hood 42. Each spout is adapted to be tilted or have its upper end flung inward, as shown at the right in Figs. 7 and 8, to a position at one side of the corresponding blower. This is sometimes necessary or desirable when a feeder or blower is not in use, or for the purpose of adjustment or repairs.

When a spout is swungto its inoperative position, a cover plate 46 is automatically moved into position to close the spout. This prevents an upward draft through the spoutfrom the chamber 42. Each cover plate 45 is carried on a pair of arms 41 provided with elongated openings 48, by means of which the arms are fulcrumed on pins 49 on the spout 40. The swinging movement of the arms 41 is controlled by a pair of rock arms 55 fulcrumed on a horizontal shaft said rock arms being formed with longitudinal slots 52 which engage pins 53 on the arms 41. Stop lugs 54 engage the arms 41 when the spout is in its operative position, and limit the swinging movement of the cover plate. The spout is held in its vertical or operative position by a latch 55 fulcrumed at 55 and engaging a lug or sleeper 51 on the spout. When it is desired to move a spout to inoperative position, as shown in full lines at the right in Fig. 7, the latch 55 is released and the spout swung inwardly; The slot and pin connection 52, 53 operates to swing the cover plate 45 over the open end of the spout thereby closing the latter.

Referring again more particularly to Figs. 1 and 2, the fibers are arrested in their downward movement through the forming hood 42, by the foraminous conveyor 44 while the steam or gas passes through the conveyor into chambers 58 therebeneath. These chambers are extended and unite to form a conduit 59 ,which includes a vertical stack or chimney 50 through which the exhaust gases may be conveyed upwardly through the building. If desired, atmospheric air may be admitted through an opening Bl leading into the spout 60. The air admitted through the opening 6! assists in cooling and condensing'the steam and is useful in maintaining and regulating the force of the blast. I

The degree of flare of the spout opening M at the marginal portions is important. Without the flare, a tremendous turbulence and vibration may be set up, together with an unbearable noise. If, on the other hand, the flare of the mouth opening 4! should be toolarge, the steam blast may blow against the curve-sides thereof and blow backwardly along the edges and sides thereof, throwing out a large quantity of wool. The flare should be relatively small, say of about inch radius, this being satisfactory for most cases in which the mouth openings are about 7 :2 2 inches in cross-sectional dimension, and the steam pressure is about 150 pounds per square inch. In any event, the flare should be designed to permit a smooth streamlined flow of a venturi type into the spout opening whereby a high steam pump effect is produced within the spout, and back pressure is minimized. The velocity of the steam which emerges from the blowers may be extremely high, and is frequently,

in the neighborhood of about seventy-five thousand feet per minute, and as much as 500 to 600 pounds of steam per hour may be passed through each spout opening. The expansion hood, however, serves to reduce the velocity thereof to a point where it may pass through the belt at a relatively slow speed of only about 500 or so feet per minute. and with 8 bushings about 25,000 cubic feet of air and steam may be carried through the belt per minute. In order to carry away this large amount of gaseous material, a belt area of about 50 square feet may be used. The lateral dimensions and the exposed area of the belt may be varied, however, within wide limits to form mats of predetermined widths.

The figures mentioned hereinabove are merely exemplary and are not to be considered as limiting or narrowing the present invention to these dimensions, sizes, rates, pressures, temperatures, etc., for it is to be understood that other conditions may be used without departing from the spirit and scope of the present invention,

The above described construction is such that the downward blast through the hood 42 is strongly maintained through the screen conveyor, without the use of suction chambers or the like beneath the conveyor. Referring to Fig. 1, it will be seen that the fibers from each pair of spouts 40 form a layer as they are'arrested by the conveyor 44. Part of the intermatting and entangling of the fibers is accomplished before they are deposited upon the belt 44. From here they are deposited in layers upon the conveyor. vidual spouts unite and the fibers are intermingled and felted or matted together so as to form an integral continuous mat 43.

As the fibers are arrested and collect upon the conveyor, they are preferably simultaneously sprayed with a suitable tempering oil or coating substance which may be applied in the form of a spray by means of the spray gun I5 at the back end or tail of the hood 42. The spray gun I5 is adjustably positioned and directed against the mat 43 as it is being formed. As illustrated in Fig. 1, the mat forms on the belt in a tapered formation which simultaneously exposes all portions of its cross-section. Each stratum, socalled, of the mat has a particular place during its formation on the belt at which it is uncovered and exposed to the atmosphere above. For example, the lowest stratum of the mat is formed at theback end of the hood, whereas the upper stratum is formed near the front end. Each stratum is exposed for approximately the same length of time before being covered up by an overlying stratum. Of course, by the use of the term stratum, it is not intended to imply that distinguishable zones of fibrous material neces sarily form. The spray nozzles are mounted in such a position and aimed in such a direction that the spray of coating substance will be projected uniformly over the entire tapered crosssection whereby substantially all of the coating substance is deposited by means of a filtering action through the unfinished mat. The vehicular gase or blast gases pass through the mat and exhaust at the outlet therefor.

The mat, as it is formed, is directed through a throat 62 and passes beneath a pressureplate 63 by which the mat is further compacted. The plate 63 is fulcrumed at its rear end by a rod 64, with the forward end of the plate resting on the mat. A weight 65 is mounted on a rod 66 fulcrumed at 61, the forward end of the rod being connected through the link 68 to the forward end of the plate 63. The downward pressure applied to the plate 63 materially assists in compacting the fibers into a mat of the desired density,- the amount of pressure being regulated by the adjustment of the weight 55. The plate 63 also prevents the passage of blast gases out through the front end of the hood.

The conveyor 44 is supported on a framework 10 and runs over rolls 1|, I2, 13, 14 and 15. The

roll 14 is carried on a takeup device 82 of con- The superposed layers from the indiventional construction for taking up slack in the conveyor 44. The conveyor is driven continuously by an electric motor 16. Power is transmitted from the motor through belt 11, pulley 18, speed reduction gearing contained within gear box 19, and a belt 8| connected to drive'the roll 12.

Heretofore, considerable difliculty has been experienced with the type of apparatus herein disclosed for carrying matted glass wool or the like on a screenor openwork conveyor, owing to the fibers working into and adhering to the conveyor. This interfered with the removal of the mat or bat from the conveyor and rendered it necessary to stop operations at intervals for cleaning the conveyor. In order to overcome this. difiiculty, we have provided stripper-or clearing mechanism 83 for automatically severing or freeingthemat from its entanglement with the wire mesh conveyor.

- This clearing mechanism'83 comprises a knife bladeor scraper 84 which overlies the conveyor 44 and extends transversely thereacross. The blade is mounted in the lower ends of a pair of vertically disposed arms 85, the upper ends of which are pivotally connected to a rod 88 mounted in a framework 81. An electric motor 88 mounted on the frame 81, drives a shaft, the ends of which are provided with cranks or eccentrics connected through links 89 to the arms 85. Coil springs 83 hold the lower sections of the arms with a yielding pressure. The motor 88 is driven continuously and thereby imparts a continuous reciprocating movement to'the arms 85 and the blade 84. The blade operates to either withdraw or sever any fibers which have become entangled in the conveyor, thereby freeing the advancing mat as a whole from entanglement with the conveyor so that the niat or the bat severed therefrom can readily be removed. The stripper 83 also prevents clogging of the conveyor, thus preventing'interference with the free passage of steam or air therethrough during the formation of the mat.

Modificatipns may be resorted to within the spirit and scope of the present invention.

We claim:

1. The method of producing an interfelted mass of glass fibers which have been produced by attenuating the fibers from a stream of molten glass by means of a high speed gaseous blast, the steps of passing said blast and said fibers through a duct having a constricted entry end so related to the source of the blast as to cooperate with said blast to produce a negative atmospheric pressure, permitting said constricted blast to induce surrounding atmospheric gases into said blast, then expanding said blast and saidinduced gases to materially reduce the velocity thereof, and then arresting the fibers at a surface transverse to the path of the gases and causing them to accumulate into a mat.

2. The method of producing an interfelted mass of glass wool fibers which have been produced by attenuating streams of molten glass by means of a high speed gaseous blast which comprises, arresting the fibers at a plane extending transversely to the direction of the blast during the range of attenuation of said fibers, said plane being spaced from the said range of attenuation of said fibers, accumulating the fibers as they are arrested and causing them to form into a mat, continually advancing said newly formed mat in a direction lying substantially in said plane, and causing said blast after attenuation of said said fibers, confining said blast to control its cross-sectional area at a point spaced from but adjacent the place of engagement of blast and stream, causing a controlled cross-sectional expansion of the path of said blast increasing gradually in the direction-of travel thereof from said 'point of confinement, and then causing the path of said blast to expand at a. higher rate and then to deposit said fibers on a foraminous arresting surface intercepting the path of the blast.

4. The process of producing a matted body of fibrous mineral material which comprises, flowing a stream of. molten mineral material, directing a blast of gas to engage said stream and causing said blast to attenuate said stream into fibers and convey said fibers, passing said blast and enveloped-fibers through a constricted passage to cause the blast. to produce a negative atmospheric pressure and to draw surrounding air into the passage, causing the path of the blast and induced, air to be gradually expanded in cross-section progressively in the direction of travel of the blast, and then arrestingthe fibers on a foraminous surface intercepting the path of the blast.

causing said blasts to conflow to permit intermingling of said fibers, and thereafter depositing said fibers on an arresting surface.

6. The method of producing matted fibrous mineral material which comprises, flowing a plurality of streams of molten mineral material, directing a plurality of blasts of a gaseous vehicle to individually engage said streams and attenuate said streams into fibers, causing said blasts to move in the region of attenuation through mutually isolated paths, causing each of said paths to expand in cross-sectional area progressively in the direction of travel of the blast, then causing the blasts to conflow to permit the fibers to intermingle, and depositing said fibers on an arresting surface.

7. In the method of forming a mass of matted fibrous mineral material by attenuating fibers of the molten material by means of a blast of gas, and causing the fibers to be advanced freely with the blast to a plane intercepting the path of the blast, the step of controlling the cross-sectional area of said gaseous blast and causing said area to increase progressively in the direction of movement of the blast from a. point closely adjacent the source of the blast and throughout at least the major portion of the travel of the blast between the source and said plane, arresting the fibers at said plane while causing the blast to continue through said plane. and thereby causing the fibers to accumulate and form a layer or web of desired. thickness while they are subject to the force of said blast.

8. The method which comprises attenuating fibers by means of a blast of gas and causing them to be advanced with and at substantially the velocity of said blast to a plane intercepting the path of said blast and removed from the point of origin of the blast, controlling the path of said blast and expanding said path progressively throughout its length beginning at a point closely adjacent but spaced from the source of the blast and terminating at said plane, whereby the pressure of said blast is controlled throughout its length of travel, arresting the fibers at said plane while the blast is driven through said plane, and accumulating the fibers as they are arrested.

9. In the art of producing an interfelted mass of mineral fibers which have been produced by attenuating the fibers from a stream of molten mineral material by means of a gaseous blast and conveyed by said blast and arrested by a foraminous surface through which said blast passes, the steps of causing said blast to pass freely through the atmosphere after engaging said stream, then causing the blast to enter a confining chamber and to pass in smooth flow with the cross-sectional area of said blast being controlled and increased progressively in the direction of its movement as said fibers are being conveyed thereby.

10. In the method of producing an interfelted mass of glass wool fibers which have been attenuated from streams of molten glass by means of a high velocity gaseous blast, the steps of constricting and guiding said blast and fibers in a smooth gradually expanding path, then directing said gases in a path progressively expanding at an increased rate to decrease the velocity thereof, and then arresting thefibers at a plane transverse to the path of how of said expanded gases.

11. In the method of producing an interfelted mass of mineral wool fibers which have been attenuated from streams of molten material by means of a high velocity gaseous blast, the steps of controlling the path of said blast and guiding said blast and fibers in smooth fiow gradually expanding in the direction of travel thereof, and inducing into said blast adjacent the source thereof surrounding atmospheric gases, thereby causing said induced gases to aid in retaining said fibers within said blast.

12. The method of producing matted fibrous mineral material which comprises, flowing a plurality of streams of molten mineral material, directing a plurality of blasts of a gaseous vehicle to individually engage said streams and attenuate said streams into fibers, causing said blasts to move in the region of attenuation through mutually isolated paths, causing each of said paths to expand in cross-sectional area progressively in the direction of travel of the blast, then causing the blasts to confiow into a single blast to permit the fibers to intermingle, guiding said single blast in a path gradually expanding in cross-sectional area to reduce the velocity of said blast and fibers,

and depositing said fibers on an arresting surface.

DALE KLEIST. GAMES SLAYTER. 

